A gas analyzer for determining the concentration of the oxides of nitrogen in a sample gas is provided. The analyzer is particularly adapted for analyzing the exhaust from an internal combustion engine. The analyzer comprises a sample chamber and a reference chamber. An arrangement is provided for delivering sample gas containing the lower oxide of nitrogen (NO) to the sample chamber and a quantity of ozone (O3) for reacting with this oxide of nitrogen and producing a chemiluminescence. After the chemiluminescence is completed, the sample gas is discharged to the reference chamber. A sample photodiode is disposed adjacent to the sample chamber for receiving light emitted from the sample chamber and producing a sample signal representative of the total photoemissivity of the sample gas. A reference photodiode is disposed adjacent to the reference chamber for receiving light emitted from the reference chamber and providing a reference signal representative of the dark current of the photodiodes and the background photoemissivity of the sample gas. A circuit is provided for conditioning and substracting the sample signal and the reference signal to produce an output representative of the concentration of the oxide of nitrogen in the sample gas. Dilution air is mixed with the sample gas either in the instrument with a viscous metering technique or in a sample probe, mounted in the exhaust of the engine, with a sonic metering technique.
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1. A gas analyzer for determining the concentration of an oxide of nitrogen in a sample gas comprising:
a sample chamber; means for delivering sample gas to said sample chamber, said sample gas containing an oxide of nitrogen; means for delivering ozone to said sample chamber for reacting with said oxide of nitrogen and producing a chemiluminescence; a reference chamber; means for discharging said sample gas from said sample chamber to said reference chamber; a sample photodiode disposed adjacent said sample chamber for receiving light emitted from said sample chamber and producing a sample signal representative of the photoemissivity of said sample gas disposed in said sample chamber; a reference photodiode disposed adjacent said reference chamber for receiving light emitted from said reference chamber and providing a reference signal representative of the dark current of said sample photodiode and the background photoemissivity of said sample gas; and means for subtracting said sample signal and said reference signal to produce an output representative of the concentration of said oxide of nitrogen in said sample gas.
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a first dilution valve having a normally open port, a normally closed port and a common port; a second dilution valve having a normally open port, a normally closed port and a common port; said common ports of said first and second dilution valves supplying gas to said sample chamber; a first flow resistance having a first predetermined value connected to said normally closed port of said first dilution valve and to a source of sample gas at said predetermined sample gas pressure; a second flow resistance having said first predetermined value connected to said normally open port of said first dilution valve and to a source of dilution air at said predetermined sample gas pressure; a third flow resistance having a second predetermined value connected to said normally closed port of said second dilution valve and to a source of sample gas at said predetermined sample gas pressure; and a fourth flow resistance having said second predetermined value connected to said normally open port of said second dilution valve and a source of dilution air at said predetermined sample gas pressure; said first and second flow resistances having values proportional to a predetermined dilution ratio whereby: a zero is established when neither of said dilution valves are actuated and only air is supplied to said sample chamber; a low range is established when both of said dilution valves are actuated and only sample gas is supplied to said sample chamber; a high range is established when one of said dilution valves is actuated and sample gas is supplied to said sample chamber through a flow resistance having said first predetermined value and dilution air is supplied to said sample chamber through a flow resistance having said second predetermined value.
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a means forming a sample sonic orifice for receiving exhaust gas; a means for forming a dilution air sonic orifice for receiving dilution air.
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The invention relates generally to a gas analyzer for determining the concentration of the oxides of nitrogen in a sample gas and more particularly is directed to a chemiluminescence NO, NO2, NOx analyzer for determining the concentration of the oxides of nitrogen in the exhaust gas of a combustion engine or power plant.
While there are five oxides of nitrogen, there are only two that are of primary concern with regard to the emissions from a combustion engine; namely, NO (nitric oxide) and NO2 (nitrogen dioxide). The total of the emissions of the oxides of nitrogen is generally referred to as NOx. Existing and forthcoming legislative measures both in the U.S. and Europe have created a need for an inexpensive and accurate analyzer for monitoring the oxides of nitrogen emissions of automotive engines. Similarly, there is much interest in monitoring the emissions from stationary power plants, or the like, and monitoring ambient concentrations of the oxides of nitrogen. Most of the NOx emitted by gasoline engines is NO which slowly oxides to NO2. However, in some combustion engines, such as in a diesel engine where compression ratios are higher and air fuel ratios are leaner, a substantial amount of NO2 is formed directly during the combustion process.
There are a number of possible techniques for measuring NO concentrations. These include nondispersive, infrared or ultraviolet gas analysis. However, infrared gas analysis of NO is difficult because the absorptivity of NO lies in a range where there is interference with water vapor. While NO has a very strong ultraviolet absorption line where water vapor would not act as a contaminate, nondispersive ultraviolet analysis has not been successful because a very selective source of ultraviolet energy is required and the sources which have been developed to date have a very short life span. The most popular technique for measuring NO in the prior art involves the principle of chemiluminescence. Chemiluminescence involves the oxidation of NO to N2 instantaneously with O3 (ozone). When this occurs, the NO2 which is formed is in an excited state and it immediately returns to its ground state giving off a photon. The photon emission of the NO2 returning to its ground state is proportional to the amount of NO in the sample gas as long as stoichiometric or greater quantities of ozone are present. The reaction takes place in approximately 10 milliseconds and for practical purposes is considered instantaneous. Thus, gas analyzers are found in the prior art which measure this chemiluminescent reaction with a photomultiplier for the purpose of producing a signal which is representative of the NO concentration in a sample gas.
In fact, the use of chemiluminescent nitric oxide detectors has become widespread in the prior art. The typical applications for such detectors are in air pollution monitoring instruments and gas analyzers for determining atmospheric concentrations of the oxides of nitrogen or the concentrations of the oxides of nitrogen in auto gas emissions, power plant emissions, etc. The success of prior art chemiluminescent detectors has almost lead to the adoption of such instruments as de facto legislative standards. However, these prior art chemiluminescent oxides of nitrogen gas analyzers have inherent problems which stem from the use of a photomultiplier for measuring the chemiluminescent reaction. Photomultipliers are vacuum tube devices which are large, fragile and expensive. It is generally difficult to supply such a tube with adequate air flow for cooling and lowering the dark current while at the same time meeting shielding requirements with regard to ambient light and radio frequency energy which substantially interfere with the operation of the device. In some prior art analyzers of this type, a thermoelectric cooled photomultiplier tube is used. While this results in an instrument having good performance, the cost of the instrument is high. Still further, although the gain of a photomultiplier tube is high, because the tube comprises a plurality of plates arrayed within a glass envelope, it is difficult to place the detector plates within close proximity to the chemiluminescent reaction. Since the photons issuing from the chemiluminescent reaction are very dispersive and difficult to focus, this can have a deleterious effect on detector sensitivity. Other problems with prior art chemiluminescent detectors in general relate to the fact that the sample gas under investigation normally contains large amounts of CO2 which has a quenching effect on the chemiluminescent reaction. The ozone requirements of these instruments is relatively high, and ozone is itself a noxious gas. The range of these instruments can be somewhat limited, and in cases where a hot gas sample is drawn from exhaust of a combustion engine, water condensate can interfere with the operation of the instrument.
According to the present invention, these and other problems in the prior art are solved by the provision of a chemiluminescent oxides of nitrogen gas analyzer featuring a pair of small, inexpensive and durable photodiodes for measuring the chemiluminescent reaction. According to another important aspect of the present invention, CO2 quenching is reduced, the instrument is provided with an extended range, ozone requirements are reduced and water condensate is substantially eliminated by mixing dilution air with the sample gas.
The gas analyzer comprises a sample chamber, an arrangement for delivering the sample gas of interest to the sample chamber and an arrangement for delivering a sufficient quantity of ozone to the sample chamber for reacting with NO and producing a chemiluminescence. A sample photodiode is disposed adjacent to the sample chamber for receiving light emitted from the sample chamber and producing a sample signal representative of the total photoemissivity of the sample gas disposed in the sample chamber. A reference chamber is provided, the reference chamber being disposed immediately adjacent to the sample chamber. A cross port is provided between the sample chamber and the reference chamber for discharging the sample gas to the reference chamber after the chemiluminescent reaction is completed. A reference photodiode is disposed adjacent the reference chamber for receiving light emitted from the reference chamber and providing a reference signal representative of both the dark current of the sample photodiodes and the background photoemissivity of the sample gas in question. The sample and reference diodes are provided with an isothermal relationship. Processing circuitry is provided for the photodiodes which includes a sample voltage follower and a reference voltage follower having high input impedances and low current leakage. Thereafter, a differential amplifier determines the difference between the output of the sample voltage follower and the reference voltage follower to provide an accurate measure of NO concentration compensated for detector noise or dark current and compensated for the background photoemissivity of the sample gas. In most cases, the NO2 concentration can be inferred from the NO concentration and total NOx can be estimated. However, in those cases where it is desirable to measure total NOx concentration, a catalyst is provided for reducing NO2 to NO prior to the chemiluminescent reaction. NO concentration can be subtracted from NOx concentration to provide an accurate measure of NO2. High-speed low capacitance planar diffusion type photodiodes are used which are small, inexpensive, durable, easily cooled, easily shielded and which feature a planar light sensitive surface which can be disposed directly adjacent to the chemiluminescent reaction to increase sensitivity.
According to another important aspect of the present invention, an arrangement is provided for introducing dilution air into the sample gas prior to delivery of the sample gas to the sample chamber. In one embodiment of the invention, the dilution air is introduced in the instrument with a viscous metering technique to provide a predetermined dilution ratio of air to sample gas. In another embodiment of the invention, the analyzer is provided with a sample probe, which is adapted for insertion in the exhaust gas of a combustion engine, and dilution air is injected in the sample probe, at the exhaust gas pressure, with a sonic metering technique. In both embodiments of the invention, dilution of the sample gas substantially eliminates CO2 quenching, extends the range of the instrument, reduces the ozone requirements of the instrument and reduces problems with water condensate in the sample gas.
FIG. 1 is an exploded assembly of the detector of the gas analyzer of the present invention;
FIG. 2 is a plan view partially in section, of the detector of the present invention;
FIG. 3(a) is a sectional view of a photodiode used in the gas analyzer of the present invention;
FIG. 3(b) is a condition band model of the photodiode illustrated in FIG. 3(a);
FIG. 4 is a plot of relative sensitive and photoemissivity versus wavelength for a typical photomultiplier, a typical photodiode and the chemiluminescent reaction between NO and O3 ;
FIG. 5 is a functional diagram of an embodiment of the gas analyzer of the present invention wherein dilution of the sample takes place in the gas analyzer;
FIG. 6 is a functional diagram of another embodiment of the gas analyzer of the present invention wherein dilution of the sample gas takes place in the tailpipe of an automotive vehicle.
FIG. 7 is a schematic representation of a voltage following circuit and differential amplifier used to process the output of the photodiodes of the gas analyzer of the present invention; and
FIG. 8 is a schematic of an instrumentation amplifier, and zero and span adjustment circuit used to process the output of the photodiodes of the gas analyzer of the present invention and input the same to a microprocessor controlled display.
With reference now to FIGS. 1 and 2 the detector assembly of the gas analyzer of the present invention is generally illustrated at 10. The detector comprises a sample chamber 11 and a reference chamber 12. A means for delivering sample gas to the sample chamber 11 is provided comprising a first concentric tube 14 extending through the back of the sample chamber 11. The sample gas which is delivered to the sample chamber contains an oxide of nitrogen preferably nitric oxide or NO. A means for delivering ozone to the sample chamber 11 is also provided comprising a second concentric tube 15 extending through the back of the sample chamber 11. The second tube 15 provides a quantity of ozone or O3 for reacting with the NO and producing a chemiluminescent reaction within the sample chamber 11. Preferably, the reference chamber 12 is disposed directly adjacent the sample chamber 11 in a common housing 16 and a means for discharging sample gas from the sample chamber 11 to the reference chamber 12 is provided comprising a cross port 17. A sample photodiode 21 is disposed immediately adjacent the sample chamber 11 for receiving light emitted from the sample chamber and producing a sample signal representative of the total photoemissivity of the sample gas disposed in the sample chamber. Similarly, a reference photodiode 22 is disposed immediately adjacent the reference chamber 12 for receiving light emitted from the reference chamber and providing a reference signal representative of both the dark current of the sample photodiode 21 and the background photoemissivity of the sample gas contained within the reference chamber. The photodiodes 21 and 22 receive light through the front face of the sample and reference chambers 11 and 12, respectively, and are mounted in windows 25 and 26 extending through gaskets 28 and 29 and heat sink 30. The reference and sample photodiodes 21 and 22 are mounted in common heat sink 30 to cool the diodes and provide them with an isothermal relationship. A circuit, illustrated in FIG. 7, is provided for subtracting the output of the reference photodiode 22 from the output of the sample photodiode 21 to produce a signal representative of the concentration of NO in the sample gas compensated for detector noise or dark current and the background photoemissivity of the sample gas.
In the prior art, it was thought that photodiodes were not suitable photodetectors for monitoring a chemiluminescent reaction such as the one between NO and O3. The photodiodes preferred in the present embodiment of the invention are a low capacitance, planar diffusion type known as the S1337 series of photodiodes available from the Hamamatsu Company of Japan. With reference now also to FIGS. 3(a) and 3(b), the cross section of the photodiodes is illustrated and the dark condition band model of the photodiodes is given. The low capacitance, planar diffusion type diode preferred for the present application is a high speed version of the typical planar diffusion type device which makes use of a highly pure, high resistance N-type material to enlarge the depletion layer and thereby increase the junction capacitance thus lowering response time to approximately one-tenth the normal value. The P-layer is also made thin to improve ultraviolet response. Since the device is in thermal equilibrium P-layer and N-layer Fermi levels are equal and a voltage gradient develops in the depletion layer by virtue of the contact potential (potential barrier).
Photodiodes were thought to be unsuitable in the prior art because the output of a photodiode is at least three orders of magnitude lower than that of a typical photomultiplier. That is to say, the typical photomultiplier provides a gain approximately one thousand times that of the typical photodiode. However, with reference to FIG. 4, which is a plot of relative sensitivity and photoemissivity versus wavelength in nanometers, curve 35 illustrates that the photoemissivity of the chemiluminescent reaction of NO and O3 extends from about 600 nanometers to about 1500 nanometers, while the sensitivity of the typical photomultiplier illustrated by curve 36 drops off significantly above 900 nanometers. On the other hand the sensitivity of the typical photodiode, illustrated at 37, starts just below 600 nanometers and extends beyond 1200 nanometers. While the sensitivities plotted in FIG. 4 are not representative of true output since the output of the typical photomultiplier is three orders of magnitude higher than the output of the typical photodiode, this plot of relative sensitivities is significant since it shows that the typical photodiode plotted at 37 has a sensitivity that more closely matches the photoemissivity of the chemiluminescent reaction plotted at 35 than that of the typical photomultiplier plotted at 36. However, it has never been thought possible to use photodiodes in this application before because of their low output and high dark current. Stated otherwise, the typical photodiode provides a low output and a poor signal to noise ratio. Nevertheless, according to the present invention, these problems are solved by providing two photodiodes in an isothermal relationship. A sample photodiode is provided for monitoring the total photoemissivity of the sample gas, including that due to chemiluminescence and a reference photodiode is provided to measure the background photoemissivity of the sample gas, as well as the dark current in the photodiodes. Operation of the photodiode pair in this manner provides good common mode rejection and a much improved signal to noise ratio. Also, as will hereinafter be described, good sample chamber design places the planar light sensitive surface of the photodiodes directly adjacent a planar chemiluminescent display which enhances sensitivity and the provision of high impedance, low leakage current voltage following circuits enables the processing circuit to "see" the low output of the photodiodes.
With specific reference again to FIGS. 1 and 2, it is illustrated that sample gas and ozone are delivered to the sample chamber 11 through concentric inner and outer tubes 14 and 15 which extend in a direction generally perpendicular to a glass window 40 which forms the front of the sample chamber 11. The concentric inner and outer tubes 14 and 15 terminate or are provided with ends which nearly abut the inside surface of the window 40. In fact, the ends of the concentric tubes 14 and 15 are separated from the inside surface of the window 40 by a distance D of approximately 0.020 inches. This arrangement and this separation distance is important to the operation of the detector since, as best illustrated by the arrows disposed within the sample cell 11 in FIG. 2, ozone and sample gas containing NO are sprayed directly on the inside surface of the glass window 40 by this arrangement to provide a planar and generally circular area of chemiluminescence which is directed on the inside surface of the glass 40. This area of chemiluminescence is thus positioned directly adjacent and parallel to the planar photosensitive surface 41 of the sample detector 21. Since the photons emitted by the chemiluminescent reaction are very dispersive, this insures the best possible response from the sample photodiode 21 and, in fact, results in a configuration much better than that possible with the typical prior art photomultiplier where it was difficult to position the detector plates of the photomultiplier directly adjacent the area of chemiluminesence because of the physical dimensions of the evacuated glass envelope within which the detector plates are enclosed.
Since the chemiluminescent reaction taking place within the sample chamber 11 is practically instantaneous, (on the order of 10 milliseconds) by the time the sample gas is discharged into the reference chamber 12 through the cross port 17, (at a typical sample flow of 2 liters/minute) the chemiluminescent reaction is terminated. The cross port 17 is provided with an angular orientation relative to the front of the sample chamber 11 and the reference chamber 12 so that light generated in the front of the sample chamber 11 from the chemiluminescent reaction does not have a clear path to the photosensitive surface 42 of the reference diode 22. Still further, the angular orientation of the cross port 17 directs the sample gas exhausted from the reference cell 11 to the inside surface of the glass window 40 of reference cell 12. Because the reference and sample photodiodes are disposed in an isothermal relationship on common heat sink 30, the reference photodiode provides an accurate measure of the dark current within the sample photodiode. However, also important to the design of the detector assembly is the fact that the reference photodiode 22 provides a measure of the background photoemissivity of the sample gas. It should be appreciated that this is important in cases where the analyzer is used to monitor the hot exhaust gas of an internal combustion engine since such an exhaust gas stream will contain hot photoemissive particles which will add to the total output of the photodetector and in effect degrade the signal to noise ratio of the instrument. However, the reference chamber 12 and reference photodiode 22 of the present invention provide an accurate measure of this background photoemissivity and provide a technique for subtracting the same from the output of the sample photodiode which contains a signal representative of the photoemissivity of the chemiluminescent reaction taking place in the detector. This is another feature considered important in the construction of a chemiluminescent oxides of nitrogen gas analyzer employing photodiodes. After a suitable residence time within the reference chamber 12, the sample gas is exhausted through line 44, extending from the back of the sample chamber 12.
As best illustrated in FIG. 1, the detector assembly comprises an aluminum housing 16 within which the sample and reference cells 11 and 12 are formed. The surfaces of the cells 11 and 12 may be painted or otherwise suitably coated with a reflective material for directing the output of the photoemissive gases contained therein toward the glass window 40 which forms the front surface of the cells. Manufacture of the cells in a common block 16 is preferred since it is desirable to minimize any temperature differential between the sample cell 11 and the reference cell 12. The tubes 14, 15 and 44 are threadably secured or otherwise suitably secured in the back of the aluminum block 16. The glass window 40 is secured to the front face of the detector housing or block 16 between Viton gaskets 28 and 29 and heat sink 30. Heat sink 30 is suitably clamped to the housing 16 with fasteners 48 or the like. Viton is a trademark of the E. I. Dupont Demour Company and identifies a fluorocarbon, elastomer material which is opaque, heat insulative and highly resistant to corrosion. These characteristics are important to the design of the detector assembly since all ambient light must be excluded from the reference and detector cells, the sample gas may be quite hot and the corrosive effects of ozone can destroy other gasket materials.
With particular reference now to FIG. 2, it is also illustrated that the gasket 28 disposed between the glass window 40 and the heat sink 30, is used to establish a small air gap 50 between the outside surface of the glass 40 and the photodiodes 21 and 22. This air gap is considered important to thermally isolate the photodiodes 21 and 22 from the hot sample gas contained within the reference and sample chambers. This, combined with the heat sink 30, lowers the operating temperature of the photodiodes 21 and 22. This is important, since heat has a deleterious effect on the operation and life of the photodiodes. It should be readily appreciated that the application of photodiqdes to a gas analyzer detector of the present type is a significant advance in the art since these diodes are relatively tough, impact resistant devices which are extremely inexpensive when compared to the typical vacuum tube type photomultiplier and which provide minimal cooling, light shielding and RF shielding requirements when compared to the typical photomultiplier. Still further, the photodiodes may be physically oriented relative to the photoemissive chemiluminescent display to enhance the output of the detector.
With reference now to FIG. 5, a functional diagram of the oxides of nitrogen gas analyzer of the present invention is generally illustrated at 55. In this case, an auto gas analyzer is illustrated, the tail pipe of the combustion engine of the automotive vehicle being schematically illustrated at 56. With respect to the previous description, like components are given the same numeral designation and the sample cell housing is illustrated at 16, the sample cell is at 11, and the reference cell is at 12. The lines 14 and 15 are illustrated entering the back of the sample cell 11 while the exhaust line 44 is illustrated leaving the back of the reference cell 12. The sample photodiode is illustrated at 21 and the reference photodiode is illustrated at 22. The analyzer includes a sample probe 60 which is adapted for placement within the exhaust pipe 56 of the combustion engine. In the case of an auto gas analyzer, the exhaust gas is often quite hot. Thus, the first concern relates to the cooling of the sample drawn from the exhaust pipe 56. According to the present invention, the hot sample gas drawn from the sample probe 60 passes through a line heat exchanger 62 comprising a pair of inner and outer concentric flexible lines 63 and 64. Generally, the flexible lines 63 and 64 are approximately 20 feet long and are formed from a flexible Teflon, polymeric material which is capable of withstanding relatively high temperatures. The effluent from the analyzer 55 is pumped back into the tail pipe 56 through the outer tube 64 in a counterflow fashion, against the sample which is drawn from the exhaust pipe 56 through the centerline 63. This, in effect, forms a counterflow line heat exchanger which sufficiently lowers the temperature of the sample gas to permit the use of flexible polymeric materials for the line 62 which interconnects the sample probe and the analyzer. This, of course, greatly facilitates the use of the analyzer, permitting flexibility in the placement of the tail pipe mounted sample probe and lowering the cost of the flexible connection extending between the tail pipe and the analyzer. The effluent from the analyzer which is pumped back to the tail pipe 56 through the outer flexible line 64 exits the sample probe 60 at a point 65 which is downstream from the inlet 66 of the sample probe.
A sample pump head disposed at 70 draws sample gas from the sample probe 60 through interior line 63 of line heat exchanger 62 to a stainless steel heat exchanger 71. The heat exchanger schematically illustrated at 71, comprises a length of stainless steel tubing having fins extending from the surface thereof which are cooled by a fan disposed within the analyzer housing. Since the exhaust gas from an internal combustion engine contains large amounts of water vapor, the gas leaving the heat exchanger 71 is normally saturated and contains a considerable amount of condensate. Thus, the sample exiting heat exchanger 71 is inputted to a low volume filter bowl and water trap at 72. The filter bowl and water trap 72 contains a sintered Teflon filter media which removes particulate material from the sample flow and the fluid collecting bowl on the bottom of the filter housing is pumped clear by a slow moving peristaltic pump 73. The peristaltic pump 73 returns the condensate via line 74 to the exterior line 64 of the line heat exchanger 62 for discharge with the effluent from the analyzer at 65 on sample probe 60.
The pressure of the sample pump head 70 is regulated by a sample regulator valve 76 which is disposed just upstream from the sample pump head 70 for introducing a predetermined amount of air to the sample pump head 70 and establishing a predetermined sample gas pressure. For example, in the present embodiment of the invention, the sample regulator valve 76 is normally adjusted to provide a sample gas pressure on line 78 of approximately 5 inches of mercury. The sample pump head 70 and sample regulator valve 76 thus determine the pressure at which sample gas is drawn from tailpipe 56 and in effect determine the delivery pressure of sample to the sample chamber 11. The output of the sample pump head 70, which contains a mixture of ambient air and cooled sample gas is directed via line 79 back to the exterior tube of line heat exchanger 62 for discharge with the remainder of the effluent of the analyzer at 65 on sample probe 60.
The analyzer further comprises an effluent pump head 80 for drawing effluent from reference chamber 12 and a effluent regulator valve is disposed at 81 for introducing air to the effluent pump head 80 and thus establishing a predetermined effluent gas pressure. In this case, the effluent regulator valve 81 is adjusted to provide an effluent gas pressure of approximately 8 inches of mercury in line 82. The output of effluent pump head 80, which comprises a mixture of cooled sample gas and air is directed via line 85 back to the exterior line 64 of line heat exchanger 62 for discharge with the remainder of the effluent of the gas analyzer at the sample probe 60. As schematically illustrated by the line 83, the pump heads 70 and 80 may be driven by a common motor. The total amount of sample gas drawn from the tailpipe 56 of the engine is approximately five liters per minute. A mixture of cooled sample gas and air is pumped back into the sample probe 60 through line heat exchanger 62 at a rate of approximately 15 liters per minute. Thus, the heat exchange capability of the concentric line heat exchanger 62 is substantial.
The sample gas drawn from an internal combustion engine normally contains significant amounts of carbon dioxide CO2 which has a quenching effect on the chemiluminescent reaction of NO and O3. Also, after cooling the sample gas is normally saturated with water so that condensate in the analyzer is a constant problem. Thus, according to the present invention, these and other problems in the prior art are solved by providing an arrangement for introducing dilution air into the sample gas prior to delivery of the sample gas to the sample chamber 11. In the present case, a dilution ratio of air to sample gas of approximately 9:1 or a turndown of approximately 9:1 is preferred. In addition to substantially eliminating problems with quenching and condensate, dilution ratios of 9:1 provide an analyzer with greater range and reduce ozone requirements. The latter is particularly important because ozone is itself a noxious gas.
In the embodiment of FIG. 5, dilution or turndown is accomplished with a viscous metering technique. More particularly, sample gas at the sample gas pressure determined by sample regulator valve 76 is delivered to the normally closed ports of first and second dilution solenoid valves SVl and SV2 via lines 90, 91 and 92. Similarly, dilution air at the sample gas pressure is delivered from regulator valve 76 via lines 94, 95 and 96 to the normally open ports of first and second dilution solenoid valves SVl and SV2. Both the valves SVl and SV2 are provided with a normally open port, a normally closed port and a common port. The common ports are connected together at 98 and form an output which is directed to the sample chamber 11. The first dilution valve SVl is provided with first and second flow resistances 101 and 102, which are connected to the normally closed port and normally open port, respectively, of valve SVl. The first and second flow resistances 101 and 102 are provided with a first predetermined flow resistance value. Similarly, the normally closed port and normally open port of valve SV2 are provided with third and fourth flow resistances 103 and 104, respectively. The third and fourth flow resistances 103 and 104 are provided with a second predetermined flow resistance value. The flow resistances 101 through 104 each comprise a capillary tube type of.flow resistance which provide a viscous metering effect. In such devices, the flow therethrough is determined by the diameter of the capillary and its length. The flow resistances 101 and 102 are sized to permit a total flow of approximately 1800 cubic centimeters (cc's) per minute. The third and fourth flow resistances 103 and 104 are sized to permit a total flow of approximately 200 cc's per minute. Thus, when sample gas flow through either of the third or fourth flow resistances 103 or 104 is mixed with dilution air flow through either one of the first and second flow resistances 101 and 102 at common point 98, between solenoid valves SVl and SV2, a turndown or dilution ratio of approximately 9:1 is achieved. Within certain viscosity limits, the effects of which are negligible in this case, this turndown ratio is constant and is determined by the dimensions of flow resistances 101 through 104.
The dilution solenoid valves SVl and SV2 are operated to provide a zero condition in the analyzer when neither of the dilution valves are actuated and only air is supplied to common point 98 through the flow resistances 102 and 104 and the normally open ports of valves SVl and SV2. A low range for the analyzer is established when both of the dilution valves SVl and SV2 are actuated and only sample gas is supplied to the common point 98 disposed therebetween from flow resistances 101 and 103 connected to the normally closed ports of valves SVl and SV2. A high range is established for the analyzer when only one of the dilution valves SVl and SV2 is actuated, such as the valve SV2 inputting approximately 1800 cc's per minute of dilution air to common point 98 through flow resistance 104 and inputting approximately 200 cc's of sample gas to common point 98 through the normally open port of valve SVl and flow resistance 102.
In the case of a gasoline engine, most of the NOx generated by the engine is NO, which readily combines with ozone to create a measurable chemiluminescent reaction. However, in the presence of oxygen, the NO slowly oxidizes to NO2. In other types of internal combustion engines such as diesel engines where air/fuel ratios are lower and the engines operate at higher compression ratios and temperatures, a certain percentage of NO2 is formed directly in the combustion process. In the present analyzer it is possible to simply measure the existing NO in the sample and then infer the NO2 content knowing the residence time of the sample within the analyzer and/or the expected percentage of N02 output of the engine which, in the case of a diesel engine, is approximately 10 percent of the total NOx output. However, where it is desirable to provide a direct measure of total NOx rather than discrete NO, a heated molebdemum or stainless steel gauze catalyst chamber is provided at 110. The catalyst contained within the chamber 110 is heated to an elevated temperature of approximately 600 degrees Celsius. and in this environment, NO2 is reduced to NO. To facilitate this process, the common point 98 between dilution solenoid valves SV1 and SV2 is connected to the common port of a third solenoid valve or divertor valve SV3. The normally open port of valve SV3 is connected to line 111 which leads to the interior tube 14 of the concentric tube arrangement injecting sample gas to the sample chamber 11. The normally closed port of valve SV3 is connected to the catalyst chamber 110, whereby upon actuation of the solenoid valve SV3, sample gas is diverted through the catalyst chamber 110 to reduce any NO2 in the sample gas stream to NO so that the chemiluminescent reaction taking place in sample gas chamber 11 is representative of the total NOx in the sample. By switching the mode of the analyzer from discrete NO and total NOx with the divertor valve SV3, an accurate measure of NO2 can be obtained by subtracting the concentration of NO from the concentration of NOx. Normally this is accomplished with software in a microprocessor which drives the analyzer display.
Ozone for the chemiluminescent reaction in sample chamber 11 is supplied through a silica gel drier 120, ozone generator 121 and an ozone capillary type flow resistance 123. Ozone is generated in the ozone generator 121 via a corona discharge created by a pair of electrodes across which an AC voltage is applied. In this case, a glass tube 125 is provided having a central electrode 126 extending therethrough and an exterior electrode 127 deposited, wound or otherwise suitably formed on the exterior of the glass tube. A suitable source of AC voltage 128 is impressed across the electrodes 126 and 127. Air is drawn axially through the glass tube 125 by the reduced pressure within sample chamber 11. Silica gel drier 120 is provided for reducing the humidity of the air entering the ozone generator 121 since high humidity can inhibit the corona discharge and the formation of ozone. The capillary flow resistance 123 is sized so as to provide a somewhat greater than stoichiometric concentration of ozone to the chemiluminescent reaction taking place in the sample chamber 11. As previously noted, the provision of a turndown of 9:1 has two additional beneficial effects on the operation of the analyzer, one of which is the provision of an analyzer having extending range, the other of which is a ten-fold reduction in ozone requirements which is important, since ozone is itself a noxious gas.
The gas analyzer further comprises a calibration solenoid valve SV4 disposed between the filter bowl 72 and the line 90 which supplies sample gas to the dilution valves SV1 and SV2. The calibration valve SV4 includes a normally open port, which is connected to filter 72 and a common port which is connected to line 90. The normally closed port of valve SV4 is connected to a source of calibration gas at 130 through control valve 131. The normally closed port of valve SV4 is also connected to a T-point 133 on line 78, which is regulated to the sample gas pressure by sample regulator valve 76 so that when the valve SV4 is actuated, the calibration gas, having a known predetermined quantity of NO, is supplied through valve SV4 at the sample gas pressure determined by regulator valve 76.
With reference now to FIG. 6, another embodiment of the gas analyzer of the present invention is illustrated wherein dilution of the sample gas takes place in the tailpipe 56 of the vehicle. As previously discussed, dilution is considered important to reduce CO2 quenching, to extend the range of the instrument, to reduce ozone requirements and to reduce problems with condensate in the analyzer. In the embodiment of FIG. 6, dilution air is pumped into the sample probe 60 where it is introduced to the sample flow with a sonic metering technique. Many components in this embodiment are similar to those in the embodiment of FIG. 5 and like components are given the same numeral designation. In this embodiment of the invention, the line heat exchanger 62 comprises inner and outer concentric, flexible Teflon lines 63 and 64 as before. However, in this case, the outer line 64 carries dilution air rather than effluent from the analyzer. Dilution air is pumped to a point 150 on sample probe 60 where it is discharged to the atmosphere adjacent to the tailpipe 56. The point 150 on sample probe 60 is downstream of the point 66 on sample probe 60 (which is preferably inside the tailpipe 56) where sample gas or exhaust gas is drawn into the sample probe. The sample probe 60 includes a filter 151 for filtering particulate matter from the sample gas flow. Flow from the filter 151 is then directed to a sample sonic orifice 155 while dilution air from point 150 is directed to a dilution air sonic orifice 156. The orifices 155 and 156 are sized such that the pressure drop across the orifices is on the order of 15 inches of mercury or more so that sonic flow is achieved in both orifices. With sonic flow conditions in an orifice, fluctuations in downstream pressure will not effect the mass flow rate through the orifice. Within practical limits, only an increase in upstream pressure will increase the flow through the orifice. The upstream pressure on the sample sonic orifice 155 is the resultant of the exhaust gas pressure and the pressure drop through the filter 151. The upstream pressure on the dilution air sonic orifice is atmospheric pressure and is regarded to be a constant. The sample sonic orifice 155 and the dilution air orifice 156 are small, sapphire orifices which are provided with diameters which are proportionate to and determine the dilution ratio of air to sample gas. The flow from the sample gas orifice 155 and the dilution air orifice 156 are combined at common point 162 which discharges the diluted sample gas flow to the interior line 63 of line heat exchanger 62. Dilution of the sample gas in the tailpipe eliminates much of the complexity and cost of the embodiment of the invention illustrated in FIG. 5 in that components such as stainless steel heat exchanger 71, filter bowl and water trap 72, condensate pump 73, dilution valves SV1 and SV2, etc., are eliminated.
Dilution air is supplied to the outer concentric line 64 of line heat exchanger 62 by a simple aquarium type dilution pump 170 which draws atmospheric air through a filter 152. The output of the pump 170 is regulated by a back pressure dilution regulator valve 171. The output of the dilution pump 170 is directed to the line heat exchanger 62 via line 172, which includes a control valve 173. Since the dilution air is exhausted to the atmosphere at point 150, dilution air is supplied to the dilution air orifice at essentially atmospheric pressure. This is regarded as a constant. A pressure sensor 175 is required to provide a measure of the exhaust gas pressure at a point 178 upstream of the sonic orifice 155. Signals from the pressure transducer 175 are inputted to a microprocessor 180 which includes a lookup table or a curve fit for modifying the actual dilution ratio and flow as it is affected by changes in the pressure of the exhaust gas.
Diluted sample gas is drawn through the interior tube 63 of line heat exchanger 62 and into the analyzer by a sample pump 181. The sample gas pressure is determined by a regulator valve 182 disposed on the input of sample pump 181. In this case, the output of sample pump 181 is simply discharged to the atmosphere. As in the previous embodiment of the invention, diluted sample gas is drawn through a divertor valve SV3 which, when energized, directs diluted sample flow through catalyst chamber 110 for reducing any NO2 in the sample gas. Diluted sample gas also flows through first calibration valve SV4. The first calibration valve SV4 includes a normally open port connected to the line heat exchanger via line 190. The common port of valve SV4 directs sample to a second calibration valve SV5. The normally closed port of first calibration valve SV4 is connected to a source of calibration gas 130. When the first calibration valve SV4 is actuated, a source of sample gas having a known concentration of NO is inputted to the sample chamber 11. The second calibration valve SV5 includes a normally open port which is connected to the common port of first calibration valve SV4 for receiving sample flow therethrough. The common port of second calibration valve SV5 is connected to the normally open port of divertor valve SV3. The normally closed port of second calibration valve SV5 is connected to a source of air so that when the second calibration valve SV5 is energized, pure air is inputted to the sample chamber 11 to zero the analyzer.
The viscous metering technique illustrated in FIG. 5 and the sonic metering technique illustrated in FIG. 6 produce another important feature of the gas analyzer of the present invention. In both cases, these metering techniques provide a means for insuring a constant flow of sample gas through the instrument which is of course important because the intensity of the chemiluminescent reaction which is monitored is affected by flow rates.
With reference now to FIG. 7, a circuit for processing the output of the sample photodetector and the reference photodetector is schematically illustrated. The circuit of FIG. 7 is considered a preamplification circuit which is normally mounted directly adjacent the heat sink 30 and photodiodes 21 and 22. The sample and reference diodes 21 and 22 are operated in a reverse bias configuration. The output of the sample and reference photodiodes are inputted to unity gain voltage following amplifiers 201 and 202, respectively. The voltage followers 201 and 202 are mounted in a common package and preferably comprise a National Semiconductor LF412CN integrated circuit having an industrial temperature range. This voltage following circuit is desirable because it has field effect transistor (FET) inputs which have very high impedances and very low leakage currents which do little to color the reaction of the photodiodes. It is preferable to employ voltage following circuits 201 and 202 on a common integrated circuit to insure that the operating conditions of both circuits are identical. This insures good common mode rejection. Power to this circuit is plus and minus 15 volts DC where indicated. The outputs of voltage following circuits 201 and 202 are inputted to a unity gain differential amplifier 204. Preferably, the differential amplifier 204 is a National Semiconductor LM11CN integrated circuit connected to a plus 15 volt and minus 15 volt DC power supply, as indicated. Also, it is preferable that the differential amplifier 204 have FET inputs. The output of the differential amplifier 204 is representative of the output of sample photodiode 21 minus the output of reference photodiode 22. The sample photodiode 21 provides an output representative of the photoemissivity of any chemiluminescent reaction, the background photoemissivity of the sample gas, as well as noise or a dark current. The reference photodiode provides a signal representative of the background photoemissivity of the sample gas and the dark current. A potentiometer at 205 is provided between the output of the reference voltage follower 202 and the differential amplifier 204 for adjusting the common mode rejection ratio of this circuit.
Although the output of the preamplifier of FIG. 7 could be inputted directly to an analog to digital (A/D) converter, and then to a microprocessor, in the preferred embodiment of the invention the output of FIG. 7 is inputted to an amplification and zero offsetting circuit illustrated in FIG. 8. The output of FIG. 7 is first inputted to a typical instrumentation amplifier comprising the three operational amplifiers U1, U2 and U4. More particularly, the output of FIG. 7 is inputted on pin 3 of operational amplifier U2 or the noninverting input of the instrumentation amplifier. The inverting input to the instrumentation amplifier or pin 3 of U1 is connected to ground and is left floating. This may provide some noise rejection capability. The instrumentation amplifier comprising operational amplifiers U1, U2 and U4 preferably comprise a National Semiconductor LM11CN integrated circuit having a gain of approximately 4000.
The output of the instrumentation amplifier is inputted to an offset amplifier U5. The offset amplifier U5 is a variable gain amplifier which can be adjusted with a span potentiometer 209 in the feedback loop of the amplifier. A zero offset value is also inputted to amplifier U5 from a zero offset amplifier U7. The amplifier U7 is a noninverting amplifier with a gain of two which adds a constant to the output of the instrumentation amplifier to determine zero. When a calibrated gas is inputted to the instrument, a span adjustment is similarly accomplished with the span potentiometer in the feedback loop of the offset amplifier U5. The output of the offset amplifier U5 is inputted to an A/D converter 210 and then to a microprocessor 180 which drives a display 220. The microprocessor 180 may include software which calculates inferred NO2 quantities from discrete measurements of NO and NOx may include curve fitting software to further compensate for temperature and pressure.
The above description should be considered exemplary and that of the preferred embodiment only. Modifications of the invention will occur to those who make and use the invention. It is desired to include within the scope of the present invention all such modifications of the invention that come within the proper scope of the appended claims.
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